//! A `MutVisitor` represents an AST modification; it accepts an AST piece and //! mutates it in place. So, for instance, macro expansion is a `MutVisitor` //! that walks over an AST and modifies it. //! //! Note: using a `MutVisitor` (other than the `MacroExpander` `MutVisitor`) on //! an AST before macro expansion is probably a bad idea. For instance, //! a `MutVisitor` renaming item names in a module will miss all of those //! that are created by the expansion of a macro. use std::ops::DerefMut; use std::panic; use rustc_data_structures::flat_map_in_place::FlatMapInPlace; use rustc_data_structures::stack::ensure_sufficient_stack; use rustc_data_structures::sync::Lrc; use rustc_span::source_map::Spanned; use rustc_span::symbol::Ident; use rustc_span::Span; use smallvec::{smallvec, Array, SmallVec}; use thin_vec::ThinVec; use crate::ast::*; use crate::ptr::P; use crate::token::{self, Token}; use crate::tokenstream::*; use crate::visit::{AssocCtxt, BoundKind}; pub trait ExpectOne { fn expect_one(self, err: &'static str) -> A::Item; } impl ExpectOne for SmallVec { fn expect_one(self, err: &'static str) -> A::Item { assert!(self.len() == 1, "{}", err); self.into_iter().next().unwrap() } } pub trait WalkItemKind { fn walk(&mut self, span: Span, id: NodeId, visitor: &mut impl MutVisitor); } pub trait MutVisitor: Sized { /// Mutable token visiting only exists for the `macro_rules` token marker and should not be /// used otherwise. Token visitor would be entirely separate from the regular visitor if /// the marker didn't have to visit AST fragments in nonterminal tokens. const VISIT_TOKENS: bool = false; // Methods in this trait have one of three forms: // // fn visit_t(&mut self, t: &mut T); // common // fn flat_map_t(&mut self, t: T) -> SmallVec<[T; 1]>; // rare // fn filter_map_t(&mut self, t: T) -> Option; // rarest // // Any additions to this trait should happen in form of a call to a public // `noop_*` function that only calls out to the visitor again, not other // `noop_*` functions. This is a necessary API workaround to the problem of // not being able to call out to the super default method in an overridden // default method. // // When writing these methods, it is better to use destructuring like this: // // fn visit_abc(&mut self, ABC { a, b, c: _ }: &mut ABC) { // visit_a(a); // visit_b(b); // } // // than to use field access like this: // // fn visit_abc(&mut self, abc: &mut ABC) { // visit_a(&mut abc.a); // visit_b(&mut abc.b); // // ignore abc.c // } // // As well as being more concise, the former is explicit about which fields // are skipped. Furthermore, if a new field is added, the destructuring // version will cause a compile error, which is good. In comparison, the // field access version will continue working and it would be easy to // forget to add handling for it. fn visit_crate(&mut self, c: &mut Crate) { walk_crate(self, c) } fn visit_meta_list_item(&mut self, list_item: &mut NestedMetaItem) { walk_meta_list_item(self, list_item); } fn visit_meta_item(&mut self, meta_item: &mut MetaItem) { walk_meta_item(self, meta_item); } fn visit_use_tree(&mut self, use_tree: &mut UseTree) { walk_use_tree(self, use_tree); } fn flat_map_foreign_item(&mut self, ni: P) -> SmallVec<[P; 1]> { walk_flat_map_item(self, ni) } fn flat_map_item(&mut self, i: P) -> SmallVec<[P; 1]> { walk_flat_map_item(self, i) } fn visit_fn_header(&mut self, header: &mut FnHeader) { walk_fn_header(self, header); } fn flat_map_field_def(&mut self, fd: FieldDef) -> SmallVec<[FieldDef; 1]> { walk_flat_map_field_def(self, fd) } fn flat_map_assoc_item( &mut self, i: P, _ctxt: AssocCtxt, ) -> SmallVec<[P; 1]> { walk_flat_map_item(self, i) } fn visit_fn_decl(&mut self, d: &mut P) { walk_fn_decl(self, d); } /// `Span` and `NodeId` are mutated at the caller site. fn visit_fn(&mut self, fk: FnKind<'_>, _: Span, _: NodeId) { walk_fn(self, fk) } fn visit_coroutine_kind(&mut self, a: &mut CoroutineKind) { walk_coroutine_kind(self, a); } fn visit_closure_binder(&mut self, b: &mut ClosureBinder) { walk_closure_binder(self, b); } fn visit_block(&mut self, b: &mut P) { walk_block(self, b); } fn flat_map_stmt(&mut self, s: Stmt) -> SmallVec<[Stmt; 1]> { walk_flat_map_stmt(self, s) } fn flat_map_arm(&mut self, arm: Arm) -> SmallVec<[Arm; 1]> { walk_flat_map_arm(self, arm) } fn visit_pat(&mut self, p: &mut P) { walk_pat(self, p); } fn visit_anon_const(&mut self, c: &mut AnonConst) { walk_anon_const(self, c); } fn visit_expr(&mut self, e: &mut P) { walk_expr(self, e); } /// This method is a hack to workaround unstable of `stmt_expr_attributes`. /// It can be removed once that feature is stabilized. fn visit_method_receiver_expr(&mut self, ex: &mut P) { self.visit_expr(ex) } fn filter_map_expr(&mut self, e: P) -> Option> { noop_filter_map_expr(self, e) } fn visit_generic_arg(&mut self, arg: &mut GenericArg) { walk_generic_arg(self, arg); } fn visit_ty(&mut self, t: &mut P) { walk_ty(self, t); } fn visit_lifetime(&mut self, l: &mut Lifetime) { walk_lifetime(self, l); } fn visit_assoc_item_constraint(&mut self, c: &mut AssocItemConstraint) { walk_assoc_item_constraint(self, c); } fn visit_foreign_mod(&mut self, nm: &mut ForeignMod) { walk_foreign_mod(self, nm); } fn flat_map_variant(&mut self, v: Variant) -> SmallVec<[Variant; 1]> { walk_flat_map_variant(self, v) } fn visit_ident(&mut self, i: &mut Ident) { walk_ident(self, i); } fn visit_path(&mut self, p: &mut Path) { walk_path(self, p); } fn visit_path_segment(&mut self, p: &mut PathSegment) { walk_path_segment(self, p) } fn visit_qself(&mut self, qs: &mut Option>) { walk_qself(self, qs); } fn visit_generic_args(&mut self, p: &mut GenericArgs) { walk_generic_args(self, p); } fn visit_angle_bracketed_parameter_data(&mut self, p: &mut AngleBracketedArgs) { walk_angle_bracketed_parameter_data(self, p); } fn visit_parenthesized_parameter_data(&mut self, p: &mut ParenthesizedArgs) { walk_parenthesized_parameter_data(self, p); } fn visit_local(&mut self, l: &mut P) { walk_local(self, l); } fn visit_mac_call(&mut self, mac: &mut MacCall) { walk_mac(self, mac); } fn visit_macro_def(&mut self, def: &mut MacroDef) { walk_macro_def(self, def); } fn visit_label(&mut self, label: &mut Label) { walk_label(self, label); } fn visit_attribute(&mut self, at: &mut Attribute) { walk_attribute(self, at); } fn flat_map_param(&mut self, param: Param) -> SmallVec<[Param; 1]> { walk_flat_map_param(self, param) } fn visit_generics(&mut self, generics: &mut Generics) { walk_generics(self, generics); } fn visit_trait_ref(&mut self, tr: &mut TraitRef) { walk_trait_ref(self, tr); } fn visit_poly_trait_ref(&mut self, p: &mut PolyTraitRef) { walk_poly_trait_ref(self, p); } fn visit_variant_data(&mut self, vdata: &mut VariantData) { walk_variant_data(self, vdata); } fn flat_map_generic_param(&mut self, param: GenericParam) -> SmallVec<[GenericParam; 1]> { walk_flat_map_generic_param(self, param) } fn visit_param_bound(&mut self, tpb: &mut GenericBound, _ctxt: BoundKind) { walk_param_bound(self, tpb); } fn visit_precise_capturing_arg(&mut self, arg: &mut PreciseCapturingArg) { walk_precise_capturing_arg(self, arg); } fn visit_mt(&mut self, mt: &mut MutTy) { walk_mt(self, mt); } fn flat_map_expr_field(&mut self, f: ExprField) -> SmallVec<[ExprField; 1]> { walk_flat_map_expr_field(self, f) } fn visit_where_clause(&mut self, where_clause: &mut WhereClause) { walk_where_clause(self, where_clause); } fn visit_where_predicate(&mut self, where_predicate: &mut WherePredicate) { walk_where_predicate(self, where_predicate); } fn visit_vis(&mut self, vis: &mut Visibility) { walk_vis(self, vis); } fn visit_id(&mut self, _id: &mut NodeId) { // Do nothing. } fn visit_span(&mut self, _sp: &mut Span) { // Do nothing. } fn flat_map_pat_field(&mut self, fp: PatField) -> SmallVec<[PatField; 1]> { walk_flat_map_pat_field(self, fp) } fn visit_inline_asm(&mut self, asm: &mut InlineAsm) { walk_inline_asm(self, asm) } fn visit_inline_asm_sym(&mut self, sym: &mut InlineAsmSym) { walk_inline_asm_sym(self, sym) } fn visit_format_args(&mut self, fmt: &mut FormatArgs) { walk_format_args(self, fmt) } fn visit_capture_by(&mut self, capture_by: &mut CaptureBy) { walk_capture_by(self, capture_by) } } /// Use a map-style function (`FnOnce(T) -> T`) to overwrite a `&mut T`. Useful /// when using a `flat_map_*` or `filter_map_*` method within a `visit_` /// method. // // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. pub fn visit_clobber(t: &mut T, f: impl FnOnce(T) -> T) { let old_t = std::mem::replace(t, T::dummy()); *t = f(old_t); } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. #[inline] fn visit_vec(elems: &mut Vec, mut visit_elem: F) where F: FnMut(&mut T), { for elem in elems { visit_elem(elem); } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. #[inline] fn visit_thin_vec(elems: &mut ThinVec, mut visit_elem: F) where F: FnMut(&mut T), { for elem in elems { visit_elem(elem); } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. #[inline] fn visit_opt(opt: &mut Option, mut visit_elem: F) where F: FnMut(&mut T), { if let Some(elem) = opt { visit_elem(elem); } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_attrs(vis: &mut T, attrs: &mut AttrVec) { for attr in attrs.iter_mut() { vis.visit_attribute(attr); } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. #[allow(unused)] fn visit_exprs(vis: &mut T, exprs: &mut Vec>) { exprs.flat_map_in_place(|expr| vis.filter_map_expr(expr)) } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_thin_exprs(vis: &mut T, exprs: &mut ThinVec>) { exprs.flat_map_in_place(|expr| vis.filter_map_expr(expr)) } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_bounds(vis: &mut T, bounds: &mut GenericBounds, ctxt: BoundKind) { visit_vec(bounds, |bound| vis.visit_param_bound(bound, ctxt)); } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_attr_args(vis: &mut T, args: &mut AttrArgs) { match args { AttrArgs::Empty => {} AttrArgs::Delimited(args) => visit_delim_args(vis, args), AttrArgs::Eq(eq_span, AttrArgsEq::Ast(expr)) => { vis.visit_expr(expr); vis.visit_span(eq_span); } AttrArgs::Eq(_eq_span, AttrArgsEq::Hir(lit)) => { unreachable!("in literal form when visiting mac args eq: {:?}", lit) } } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_delim_args(vis: &mut T, args: &mut DelimArgs) { let DelimArgs { dspan, delim: _, tokens } = args; visit_tts(vis, tokens); visit_delim_span(vis, dspan); } pub fn visit_delim_span(vis: &mut T, DelimSpan { open, close }: &mut DelimSpan) { vis.visit_span(open); vis.visit_span(close); } pub fn walk_flat_map_pat_field( vis: &mut T, mut fp: PatField, ) -> SmallVec<[PatField; 1]> { let PatField { attrs, id, ident, is_placeholder: _, is_shorthand: _, pat, span } = &mut fp; vis.visit_id(id); visit_attrs(vis, attrs); vis.visit_ident(ident); vis.visit_pat(pat); vis.visit_span(span); smallvec![fp] } fn walk_use_tree(vis: &mut T, use_tree: &mut UseTree) { let UseTree { prefix, kind, span } = use_tree; vis.visit_path(prefix); match kind { UseTreeKind::Simple(rename) => visit_opt(rename, |rename| vis.visit_ident(rename)), UseTreeKind::Nested { items, span } => { for (tree, id) in items { vis.visit_id(id); vis.visit_use_tree(tree); } vis.visit_span(span); } UseTreeKind::Glob => {} } vis.visit_span(span); } pub fn walk_flat_map_arm(vis: &mut T, mut arm: Arm) -> SmallVec<[Arm; 1]> { let Arm { attrs, pat, guard, body, span, id, is_placeholder: _ } = &mut arm; vis.visit_id(id); visit_attrs(vis, attrs); vis.visit_pat(pat); visit_opt(guard, |guard| vis.visit_expr(guard)); visit_opt(body, |body| vis.visit_expr(body)); vis.visit_span(span); smallvec![arm] } fn walk_assoc_item_constraint( vis: &mut T, AssocItemConstraint { id, ident, gen_args, kind, span }: &mut AssocItemConstraint, ) { vis.visit_id(id); vis.visit_ident(ident); if let Some(gen_args) = gen_args { vis.visit_generic_args(gen_args); } match kind { AssocItemConstraintKind::Equality { term } => match term { Term::Ty(ty) => vis.visit_ty(ty), Term::Const(c) => vis.visit_anon_const(c), }, AssocItemConstraintKind::Bound { bounds } => visit_bounds(vis, bounds, BoundKind::Bound), } vis.visit_span(span); } pub fn walk_ty(vis: &mut T, ty: &mut P) { let Ty { id, kind, span, tokens } = ty.deref_mut(); vis.visit_id(id); match kind { TyKind::Err(_guar) => {} TyKind::Infer | TyKind::ImplicitSelf | TyKind::Dummy | TyKind::Never | TyKind::CVarArgs => { } TyKind::Slice(ty) => vis.visit_ty(ty), TyKind::Ptr(mt) => vis.visit_mt(mt), TyKind::Ref(lt, mt) => { visit_opt(lt, |lt| vis.visit_lifetime(lt)); vis.visit_mt(mt); } TyKind::BareFn(bft) => { let BareFnTy { safety, ext: _, generic_params, decl, decl_span } = bft.deref_mut(); visit_safety(vis, safety); generic_params.flat_map_in_place(|param| vis.flat_map_generic_param(param)); vis.visit_fn_decl(decl); vis.visit_span(decl_span); } TyKind::Tup(tys) => visit_thin_vec(tys, |ty| vis.visit_ty(ty)), TyKind::Paren(ty) => vis.visit_ty(ty), TyKind::Pat(ty, pat) => { vis.visit_ty(ty); vis.visit_pat(pat); } TyKind::Path(qself, path) => { vis.visit_qself(qself); vis.visit_path(path); } TyKind::Array(ty, length) => { vis.visit_ty(ty); vis.visit_anon_const(length); } TyKind::Typeof(expr) => vis.visit_anon_const(expr), TyKind::TraitObject(bounds, _syntax) => { visit_vec(bounds, |bound| vis.visit_param_bound(bound, BoundKind::TraitObject)) } TyKind::ImplTrait(id, bounds) => { vis.visit_id(id); visit_vec(bounds, |bound| vis.visit_param_bound(bound, BoundKind::Impl)); } TyKind::MacCall(mac) => vis.visit_mac_call(mac), TyKind::AnonStruct(id, fields) | TyKind::AnonUnion(id, fields) => { vis.visit_id(id); fields.flat_map_in_place(|field| vis.flat_map_field_def(field)); } } visit_lazy_tts(vis, tokens); vis.visit_span(span); } fn walk_foreign_mod(vis: &mut T, foreign_mod: &mut ForeignMod) { let ForeignMod { safety, abi: _, items } = foreign_mod; visit_safety(vis, safety); items.flat_map_in_place(|item| vis.flat_map_foreign_item(item)); } pub fn walk_flat_map_variant( visitor: &mut T, mut variant: Variant, ) -> SmallVec<[Variant; 1]> { let Variant { ident, vis, attrs, id, data, disr_expr, span, is_placeholder: _ } = &mut variant; visitor.visit_id(id); visit_attrs(visitor, attrs); visitor.visit_vis(vis); visitor.visit_ident(ident); visitor.visit_variant_data(data); visit_opt(disr_expr, |disr_expr| visitor.visit_anon_const(disr_expr)); visitor.visit_span(span); smallvec![variant] } fn walk_ident(vis: &mut T, Ident { name: _, span }: &mut Ident) { vis.visit_span(span); } fn walk_path_segment(vis: &mut T, segment: &mut PathSegment) { let PathSegment { ident, id, args } = segment; vis.visit_id(id); vis.visit_ident(ident); visit_opt(args, |args| vis.visit_generic_args(args)); } fn walk_path(vis: &mut T, Path { segments, span, tokens }: &mut Path) { for segment in segments { vis.visit_path_segment(segment); } visit_lazy_tts(vis, tokens); vis.visit_span(span); } fn walk_qself(vis: &mut T, qself: &mut Option>) { visit_opt(qself, |qself| { let QSelf { ty, path_span, position: _ } = &mut **qself; vis.visit_ty(ty); vis.visit_span(path_span); }) } fn walk_generic_args(vis: &mut T, generic_args: &mut GenericArgs) { match generic_args { GenericArgs::AngleBracketed(data) => vis.visit_angle_bracketed_parameter_data(data), GenericArgs::Parenthesized(data) => vis.visit_parenthesized_parameter_data(data), GenericArgs::ParenthesizedElided(span) => vis.visit_span(span), } } fn walk_generic_arg(vis: &mut T, arg: &mut GenericArg) { match arg { GenericArg::Lifetime(lt) => vis.visit_lifetime(lt), GenericArg::Type(ty) => vis.visit_ty(ty), GenericArg::Const(ct) => vis.visit_anon_const(ct), } } fn walk_angle_bracketed_parameter_data(vis: &mut T, data: &mut AngleBracketedArgs) { let AngleBracketedArgs { args, span } = data; visit_thin_vec(args, |arg| match arg { AngleBracketedArg::Arg(arg) => vis.visit_generic_arg(arg), AngleBracketedArg::Constraint(constraint) => vis.visit_assoc_item_constraint(constraint), }); vis.visit_span(span); } fn walk_parenthesized_parameter_data(vis: &mut T, args: &mut ParenthesizedArgs) { let ParenthesizedArgs { inputs, output, span, inputs_span } = args; visit_thin_vec(inputs, |input| vis.visit_ty(input)); walk_fn_ret_ty(vis, output); vis.visit_span(span); vis.visit_span(inputs_span); } fn walk_local(vis: &mut T, local: &mut P) { let Local { id, pat, ty, kind, span, colon_sp, attrs, tokens } = local.deref_mut(); vis.visit_id(id); visit_attrs(vis, attrs); vis.visit_pat(pat); visit_opt(ty, |ty| vis.visit_ty(ty)); match kind { LocalKind::Decl => {} LocalKind::Init(init) => { vis.visit_expr(init); } LocalKind::InitElse(init, els) => { vis.visit_expr(init); vis.visit_block(els); } } visit_lazy_tts(vis, tokens); visit_opt(colon_sp, |sp| vis.visit_span(sp)); vis.visit_span(span); } fn walk_attribute(vis: &mut T, attr: &mut Attribute) { let Attribute { kind, id: _, style: _, span } = attr; match kind { AttrKind::Normal(normal) => { let NormalAttr { item: AttrItem { unsafety: _, path, args, tokens }, tokens: attr_tokens, } = &mut **normal; vis.visit_path(path); visit_attr_args(vis, args); visit_lazy_tts(vis, tokens); visit_lazy_tts(vis, attr_tokens); } AttrKind::DocComment(_kind, _sym) => {} } vis.visit_span(span); } fn walk_mac(vis: &mut T, mac: &mut MacCall) { let MacCall { path, args } = mac; vis.visit_path(path); visit_delim_args(vis, args); } fn walk_macro_def(vis: &mut T, macro_def: &mut MacroDef) { let MacroDef { body, macro_rules: _ } = macro_def; visit_delim_args(vis, body); } fn walk_meta_list_item(vis: &mut T, li: &mut NestedMetaItem) { match li { NestedMetaItem::MetaItem(mi) => vis.visit_meta_item(mi), NestedMetaItem::Lit(_lit) => {} } } fn walk_meta_item(vis: &mut T, mi: &mut MetaItem) { let MetaItem { unsafety: _, path: _, kind, span } = mi; match kind { MetaItemKind::Word => {} MetaItemKind::List(mis) => visit_thin_vec(mis, |mi| vis.visit_meta_list_item(mi)), MetaItemKind::NameValue(_s) => {} } vis.visit_span(span); } pub fn walk_flat_map_param(vis: &mut T, mut param: Param) -> SmallVec<[Param; 1]> { let Param { attrs, id, pat, span, ty, is_placeholder: _ } = &mut param; vis.visit_id(id); visit_attrs(vis, attrs); vis.visit_pat(pat); vis.visit_ty(ty); vis.visit_span(span); smallvec![param] } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_attr_tt(vis: &mut T, tt: &mut AttrTokenTree) { match tt { AttrTokenTree::Token(token, _spacing) => { visit_token(vis, token); } AttrTokenTree::Delimited(dspan, _spacing, _delim, tts) => { visit_attr_tts(vis, tts); visit_delim_span(vis, dspan); } AttrTokenTree::AttrsTarget(AttrsTarget { attrs, tokens }) => { visit_attrs(vis, attrs); visit_lazy_tts_opt_mut(vis, Some(tokens)); } } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_tt(vis: &mut T, tt: &mut TokenTree) { match tt { TokenTree::Token(token, _spacing) => { visit_token(vis, token); } TokenTree::Delimited(dspan, _spacing, _delim, tts) => { visit_tts(vis, tts); visit_delim_span(vis, dspan); } } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_tts(vis: &mut T, TokenStream(tts): &mut TokenStream) { if T::VISIT_TOKENS && !tts.is_empty() { let tts = Lrc::make_mut(tts); visit_vec(tts, |tree| visit_tt(vis, tree)); } } fn visit_attr_tts(vis: &mut T, AttrTokenStream(tts): &mut AttrTokenStream) { if T::VISIT_TOKENS && !tts.is_empty() { let tts = Lrc::make_mut(tts); visit_vec(tts, |tree| visit_attr_tt(vis, tree)); } } fn visit_lazy_tts_opt_mut(vis: &mut T, lazy_tts: Option<&mut LazyAttrTokenStream>) { if T::VISIT_TOKENS { if let Some(lazy_tts) = lazy_tts { let mut tts = lazy_tts.to_attr_token_stream(); visit_attr_tts(vis, &mut tts); *lazy_tts = LazyAttrTokenStream::new(tts); } } } fn visit_lazy_tts(vis: &mut T, lazy_tts: &mut Option) { visit_lazy_tts_opt_mut(vis, lazy_tts.as_mut()); } /// Applies ident visitor if it's an ident; applies other visits to interpolated nodes. /// In practice the ident part is not actually used by specific visitors right now, /// but there's a test below checking that it works. // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. pub fn visit_token(vis: &mut T, t: &mut Token) { let Token { kind, span } = t; match kind { token::Ident(name, _is_raw) | token::Lifetime(name, _is_raw) => { let mut ident = Ident::new(*name, *span); vis.visit_ident(&mut ident); *name = ident.name; *span = ident.span; return; // Avoid visiting the span for the second time. } token::NtIdent(ident, _is_raw) => { vis.visit_ident(ident); } token::NtLifetime(ident, _is_raw) => { vis.visit_ident(ident); } token::Interpolated(nt) => { let nt = Lrc::make_mut(nt); visit_nonterminal(vis, nt); } _ => {} } vis.visit_span(span); } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. /// Applies the visitor to elements of interpolated nodes. // // N.B., this can occur only when applying a visitor to partially expanded // code, where parsed pieces have gotten implanted ito *other* macro // invocations. This is relevant for macro hygiene, but possibly not elsewhere. // // One problem here occurs because the types for flat_map_item, flat_map_stmt, // etc., allow the visitor to return *multiple* items; this is a problem for the // nodes here, because they insist on having exactly one piece. One solution // would be to mangle the MutVisitor trait to include one-to-many and // one-to-one versions of these entry points, but that would probably confuse a // lot of people and help very few. Instead, I'm just going to put in dynamic // checks. I think the performance impact of this will be pretty much // nonexistent. The danger is that someone will apply a `MutVisitor` to a // partially expanded node, and will be confused by the fact that their // `flat_map_item` or `flat_map_stmt` isn't getting called on `NtItem` or `NtStmt` // nodes. Hopefully they'll wind up reading this comment, and doing something // appropriate. // // BTW, design choice: I considered just changing the type of, e.g., `NtItem` to // contain multiple items, but decided against it when I looked at // `parse_item_or_view_item` and tried to figure out what I would do with // multiple items there.... fn visit_nonterminal(vis: &mut T, nt: &mut token::Nonterminal) { match nt { token::NtItem(item) => visit_clobber(item, |item| { // This is probably okay, because the only visitors likely to // peek inside interpolated nodes will be renamings/markings, // which map single items to single items. vis.flat_map_item(item).expect_one("expected visitor to produce exactly one item") }), token::NtBlock(block) => vis.visit_block(block), token::NtStmt(stmt) => visit_clobber(stmt, |stmt| { // See reasoning above. stmt.map(|stmt| { vis.flat_map_stmt(stmt).expect_one("expected visitor to produce exactly one item") }) }), token::NtPat(pat) => vis.visit_pat(pat), token::NtExpr(expr) => vis.visit_expr(expr), token::NtTy(ty) => vis.visit_ty(ty), token::NtLiteral(expr) => vis.visit_expr(expr), token::NtMeta(item) => { let AttrItem { unsafety: _, path, args, tokens } = item.deref_mut(); vis.visit_path(path); visit_attr_args(vis, args); visit_lazy_tts(vis, tokens); } token::NtPath(path) => vis.visit_path(path), token::NtVis(visib) => vis.visit_vis(visib), } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_defaultness(vis: &mut T, defaultness: &mut Defaultness) { match defaultness { Defaultness::Default(span) => vis.visit_span(span), Defaultness::Final => {} } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_safety(vis: &mut T, safety: &mut Safety) { match safety { Safety::Unsafe(span) => vis.visit_span(span), Safety::Safe(span) => vis.visit_span(span), Safety::Default => {} } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_polarity(vis: &mut T, polarity: &mut ImplPolarity) { match polarity { ImplPolarity::Positive => {} ImplPolarity::Negative(span) => vis.visit_span(span), } } // No `noop_` prefix because there isn't a corresponding method in `MutVisitor`. fn visit_constness(vis: &mut T, constness: &mut Const) { match constness { Const::Yes(span) => vis.visit_span(span), Const::No => {} } } fn walk_closure_binder(vis: &mut T, binder: &mut ClosureBinder) { match binder { ClosureBinder::NotPresent => {} ClosureBinder::For { span: _, generic_params } => { generic_params.flat_map_in_place(|param| vis.flat_map_generic_param(param)); } } } fn walk_coroutine_kind(vis: &mut T, coroutine_kind: &mut CoroutineKind) { match coroutine_kind { CoroutineKind::Async { span, closure_id, return_impl_trait_id } | CoroutineKind::Gen { span, closure_id, return_impl_trait_id } | CoroutineKind::AsyncGen { span, closure_id, return_impl_trait_id } => { vis.visit_id(closure_id); vis.visit_id(return_impl_trait_id); vis.visit_span(span); } } } fn walk_fn(vis: &mut T, kind: FnKind<'_>) { match kind { FnKind::Fn(FnSig { header, decl, span }, generics, body) => { // Identifier and visibility are visited as a part of the item. vis.visit_fn_header(header); vis.visit_generics(generics); vis.visit_fn_decl(decl); if let Some(body) = body { vis.visit_block(body); } vis.visit_span(span); } FnKind::Closure(binder, decl, body) => { vis.visit_closure_binder(binder); vis.visit_fn_decl(decl); vis.visit_expr(body); } } } fn walk_fn_decl(vis: &mut T, decl: &mut P) { let FnDecl { inputs, output } = decl.deref_mut(); inputs.flat_map_in_place(|param| vis.flat_map_param(param)); walk_fn_ret_ty(vis, output); } fn walk_fn_ret_ty(vis: &mut T, fn_ret_ty: &mut FnRetTy) { match fn_ret_ty { FnRetTy::Default(span) => vis.visit_span(span), FnRetTy::Ty(ty) => vis.visit_ty(ty), } } fn walk_param_bound(vis: &mut T, pb: &mut GenericBound) { match pb { GenericBound::Trait(ty, _modifier) => vis.visit_poly_trait_ref(ty), GenericBound::Outlives(lifetime) => walk_lifetime(vis, lifetime), GenericBound::Use(args, span) => { for arg in args { vis.visit_precise_capturing_arg(arg); } vis.visit_span(span); } } } fn walk_precise_capturing_arg(vis: &mut T, arg: &mut PreciseCapturingArg) { match arg { PreciseCapturingArg::Lifetime(lt) => { vis.visit_lifetime(lt); } PreciseCapturingArg::Arg(path, id) => { vis.visit_id(id); vis.visit_path(path); } } } pub fn walk_flat_map_generic_param( vis: &mut T, mut param: GenericParam, ) -> SmallVec<[GenericParam; 1]> { let GenericParam { id, ident, attrs, bounds, kind, colon_span, is_placeholder: _ } = &mut param; vis.visit_id(id); visit_attrs(vis, attrs); vis.visit_ident(ident); visit_vec(bounds, |bound| vis.visit_param_bound(bound, BoundKind::Bound)); match kind { GenericParamKind::Lifetime => {} GenericParamKind::Type { default } => { visit_opt(default, |default| vis.visit_ty(default)); } GenericParamKind::Const { ty, kw_span: _, default } => { vis.visit_ty(ty); visit_opt(default, |default| vis.visit_anon_const(default)); } } if let Some(colon_span) = colon_span { vis.visit_span(colon_span); } smallvec![param] } fn walk_label(vis: &mut T, Label { ident }: &mut Label) { vis.visit_ident(ident); } fn walk_lifetime(vis: &mut T, Lifetime { id, ident }: &mut Lifetime) { vis.visit_id(id); vis.visit_ident(ident); } fn walk_generics(vis: &mut T, generics: &mut Generics) { let Generics { params, where_clause, span } = generics; params.flat_map_in_place(|param| vis.flat_map_generic_param(param)); vis.visit_where_clause(where_clause); vis.visit_span(span); } fn walk_ty_alias_where_clauses(vis: &mut T, tawcs: &mut TyAliasWhereClauses) { let TyAliasWhereClauses { before, after, split: _ } = tawcs; let TyAliasWhereClause { has_where_token: _, span: span_before } = before; let TyAliasWhereClause { has_where_token: _, span: span_after } = after; vis.visit_span(span_before); vis.visit_span(span_after); } fn walk_where_clause(vis: &mut T, wc: &mut WhereClause) { let WhereClause { has_where_token: _, predicates, span } = wc; visit_thin_vec(predicates, |predicate| vis.visit_where_predicate(predicate)); vis.visit_span(span); } fn walk_where_predicate(vis: &mut T, pred: &mut WherePredicate) { match pred { WherePredicate::BoundPredicate(bp) => { let WhereBoundPredicate { span, bound_generic_params, bounded_ty, bounds } = bp; bound_generic_params.flat_map_in_place(|param| vis.flat_map_generic_param(param)); vis.visit_ty(bounded_ty); visit_vec(bounds, |bound| vis.visit_param_bound(bound, BoundKind::Bound)); vis.visit_span(span); } WherePredicate::RegionPredicate(rp) => { let WhereRegionPredicate { span, lifetime, bounds } = rp; vis.visit_lifetime(lifetime); visit_vec(bounds, |bound| vis.visit_param_bound(bound, BoundKind::Bound)); vis.visit_span(span); } WherePredicate::EqPredicate(ep) => { let WhereEqPredicate { span, lhs_ty, rhs_ty } = ep; vis.visit_ty(lhs_ty); vis.visit_ty(rhs_ty); vis.visit_span(span); } } } fn walk_variant_data(vis: &mut T, vdata: &mut VariantData) { match vdata { VariantData::Struct { fields, recovered: _ } => { fields.flat_map_in_place(|field| vis.flat_map_field_def(field)); } VariantData::Tuple(fields, id) => { vis.visit_id(id); fields.flat_map_in_place(|field| vis.flat_map_field_def(field)); } VariantData::Unit(id) => vis.visit_id(id), } } fn walk_trait_ref(vis: &mut T, TraitRef { path, ref_id }: &mut TraitRef) { vis.visit_id(ref_id); vis.visit_path(path); } fn walk_poly_trait_ref(vis: &mut T, p: &mut PolyTraitRef) { let PolyTraitRef { bound_generic_params, trait_ref, span } = p; bound_generic_params.flat_map_in_place(|param| vis.flat_map_generic_param(param)); vis.visit_trait_ref(trait_ref); vis.visit_span(span); } pub fn walk_flat_map_field_def( visitor: &mut T, mut fd: FieldDef, ) -> SmallVec<[FieldDef; 1]> { let FieldDef { span, ident, vis, id, ty, attrs, is_placeholder: _ } = &mut fd; visitor.visit_id(id); visit_attrs(visitor, attrs); visitor.visit_vis(vis); visit_opt(ident, |ident| visitor.visit_ident(ident)); visitor.visit_ty(ty); visitor.visit_span(span); smallvec![fd] } pub fn walk_flat_map_expr_field( vis: &mut T, mut f: ExprField, ) -> SmallVec<[ExprField; 1]> { let ExprField { ident, expr, span, is_shorthand: _, attrs, id, is_placeholder: _ } = &mut f; vis.visit_id(id); visit_attrs(vis, attrs); vis.visit_ident(ident); vis.visit_expr(expr); vis.visit_span(span); smallvec![f] } fn walk_mt(vis: &mut T, MutTy { ty, mutbl: _ }: &mut MutTy) { vis.visit_ty(ty); } pub fn walk_block(vis: &mut T, block: &mut P) { let Block { id, stmts, rules: _, span, tokens, could_be_bare_literal: _ } = block.deref_mut(); vis.visit_id(id); stmts.flat_map_in_place(|stmt| vis.flat_map_stmt(stmt)); visit_lazy_tts(vis, tokens); vis.visit_span(span); } pub fn walk_item_kind( kind: &mut impl WalkItemKind, span: Span, id: NodeId, vis: &mut impl MutVisitor, ) { kind.walk(span, id, vis) } impl WalkItemKind for ItemKind { fn walk(&mut self, span: Span, id: NodeId, vis: &mut impl MutVisitor) { match self { ItemKind::ExternCrate(_orig_name) => {} ItemKind::Use(use_tree) => vis.visit_use_tree(use_tree), ItemKind::Static(box StaticItem { ty, safety: _, mutability: _, expr }) => { vis.visit_ty(ty); visit_opt(expr, |expr| vis.visit_expr(expr)); } ItemKind::Const(item) => { visit_const_item(item, vis); } ItemKind::Fn(box Fn { defaultness, generics, sig, body }) => { visit_defaultness(vis, defaultness); vis.visit_fn(FnKind::Fn(sig, generics, body), span, id); } ItemKind::Mod(safety, mod_kind) => { visit_safety(vis, safety); match mod_kind { ModKind::Loaded(items, _inline, ModSpans { inner_span, inject_use_span }) => { items.flat_map_in_place(|item| vis.flat_map_item(item)); vis.visit_span(inner_span); vis.visit_span(inject_use_span); } ModKind::Unloaded => {} } } ItemKind::ForeignMod(nm) => vis.visit_foreign_mod(nm), ItemKind::GlobalAsm(asm) => vis.visit_inline_asm(asm), ItemKind::TyAlias(box TyAlias { defaultness, generics, where_clauses, bounds, ty }) => { visit_defaultness(vis, defaultness); vis.visit_generics(generics); visit_bounds(vis, bounds, BoundKind::Bound); visit_opt(ty, |ty| vis.visit_ty(ty)); walk_ty_alias_where_clauses(vis, where_clauses); } ItemKind::Enum(EnumDef { variants }, generics) => { vis.visit_generics(generics); variants.flat_map_in_place(|variant| vis.flat_map_variant(variant)); } ItemKind::Struct(variant_data, generics) | ItemKind::Union(variant_data, generics) => { vis.visit_generics(generics); vis.visit_variant_data(variant_data); } ItemKind::Impl(box Impl { defaultness, safety, generics, constness, polarity, of_trait, self_ty, items, }) => { visit_defaultness(vis, defaultness); visit_safety(vis, safety); vis.visit_generics(generics); visit_constness(vis, constness); visit_polarity(vis, polarity); visit_opt(of_trait, |trait_ref| vis.visit_trait_ref(trait_ref)); vis.visit_ty(self_ty); items.flat_map_in_place(|item| vis.flat_map_assoc_item(item, AssocCtxt::Impl)); } ItemKind::Trait(box Trait { safety, is_auto: _, generics, bounds, items }) => { visit_safety(vis, safety); vis.visit_generics(generics); visit_bounds(vis, bounds, BoundKind::Bound); items.flat_map_in_place(|item| vis.flat_map_assoc_item(item, AssocCtxt::Trait)); } ItemKind::TraitAlias(generics, bounds) => { vis.visit_generics(generics); visit_bounds(vis, bounds, BoundKind::Bound); } ItemKind::MacCall(m) => vis.visit_mac_call(m), ItemKind::MacroDef(def) => vis.visit_macro_def(def), ItemKind::Delegation(box Delegation { id, qself, path, rename, body, from_glob: _, }) => { vis.visit_id(id); vis.visit_qself(qself); vis.visit_path(path); if let Some(rename) = rename { vis.visit_ident(rename); } if let Some(body) = body { vis.visit_block(body); } } ItemKind::DelegationMac(box DelegationMac { qself, prefix, suffixes, body }) => { vis.visit_qself(qself); vis.visit_path(prefix); if let Some(suffixes) = suffixes { for (ident, rename) in suffixes { vis.visit_ident(ident); if let Some(rename) = rename { vis.visit_ident(rename); } } } if let Some(body) = body { vis.visit_block(body); } } } } } impl WalkItemKind for AssocItemKind { fn walk(&mut self, span: Span, id: NodeId, visitor: &mut impl MutVisitor) { match self { AssocItemKind::Const(item) => { visit_const_item(item, visitor); } AssocItemKind::Fn(box Fn { defaultness, generics, sig, body }) => { visit_defaultness(visitor, defaultness); visitor.visit_fn(FnKind::Fn(sig, generics, body), span, id); } AssocItemKind::Type(box TyAlias { defaultness, generics, where_clauses, bounds, ty, }) => { visit_defaultness(visitor, defaultness); visitor.visit_generics(generics); visit_bounds(visitor, bounds, BoundKind::Bound); visit_opt(ty, |ty| visitor.visit_ty(ty)); walk_ty_alias_where_clauses(visitor, where_clauses); } AssocItemKind::MacCall(mac) => visitor.visit_mac_call(mac), AssocItemKind::Delegation(box Delegation { id, qself, path, rename, body, from_glob: _, }) => { visitor.visit_id(id); visitor.visit_qself(qself); visitor.visit_path(path); if let Some(rename) = rename { visitor.visit_ident(rename); } if let Some(body) = body { visitor.visit_block(body); } } AssocItemKind::DelegationMac(box DelegationMac { qself, prefix, suffixes, body }) => { visitor.visit_qself(qself); visitor.visit_path(prefix); if let Some(suffixes) = suffixes { for (ident, rename) in suffixes { visitor.visit_ident(ident); if let Some(rename) = rename { visitor.visit_ident(rename); } } } if let Some(body) = body { visitor.visit_block(body); } } } } } fn visit_const_item( ConstItem { defaultness, generics, ty, expr }: &mut ConstItem, visitor: &mut T, ) { visit_defaultness(visitor, defaultness); visitor.visit_generics(generics); visitor.visit_ty(ty); visit_opt(expr, |expr| visitor.visit_expr(expr)); } fn walk_fn_header(vis: &mut T, header: &mut FnHeader) { let FnHeader { safety, coroutine_kind, constness, ext: _ } = header; visit_constness(vis, constness); coroutine_kind.as_mut().map(|coroutine_kind| vis.visit_coroutine_kind(coroutine_kind)); visit_safety(vis, safety); } pub fn walk_crate(vis: &mut T, krate: &mut Crate) { let Crate { attrs, items, spans, id, is_placeholder: _ } = krate; vis.visit_id(id); visit_attrs(vis, attrs); items.flat_map_in_place(|item| vis.flat_map_item(item)); let ModSpans { inner_span, inject_use_span } = spans; vis.visit_span(inner_span); vis.visit_span(inject_use_span); } /// Mutates one item, returning the item again. pub fn walk_flat_map_item( visitor: &mut impl MutVisitor, mut item: P>, ) -> SmallVec<[P>; 1]> { let Item { ident, attrs, id, kind, vis, span, tokens } = item.deref_mut(); visitor.visit_id(id); visit_attrs(visitor, attrs); visitor.visit_vis(vis); visitor.visit_ident(ident); kind.walk(*span, *id, visitor); visit_lazy_tts(visitor, tokens); visitor.visit_span(span); smallvec![item] } impl WalkItemKind for ForeignItemKind { fn walk(&mut self, span: Span, id: NodeId, visitor: &mut impl MutVisitor) { match self { ForeignItemKind::Static(box StaticItem { ty, mutability: _, expr, safety: _ }) => { visitor.visit_ty(ty); visit_opt(expr, |expr| visitor.visit_expr(expr)); } ForeignItemKind::Fn(box Fn { defaultness, generics, sig, body }) => { visit_defaultness(visitor, defaultness); visitor.visit_fn(FnKind::Fn(sig, generics, body), span, id); } ForeignItemKind::TyAlias(box TyAlias { defaultness, generics, where_clauses, bounds, ty, }) => { visit_defaultness(visitor, defaultness); visitor.visit_generics(generics); visit_bounds(visitor, bounds, BoundKind::Bound); visit_opt(ty, |ty| visitor.visit_ty(ty)); walk_ty_alias_where_clauses(visitor, where_clauses); } ForeignItemKind::MacCall(mac) => visitor.visit_mac_call(mac), } } } pub fn walk_pat(vis: &mut T, pat: &mut P) { let Pat { id, kind, span, tokens } = pat.deref_mut(); vis.visit_id(id); match kind { PatKind::Err(_guar) => {} PatKind::Wild | PatKind::Rest | PatKind::Never => {} PatKind::Ident(_binding_mode, ident, sub) => { vis.visit_ident(ident); visit_opt(sub, |sub| vis.visit_pat(sub)); } PatKind::Lit(e) => vis.visit_expr(e), PatKind::TupleStruct(qself, path, elems) => { vis.visit_qself(qself); vis.visit_path(path); visit_thin_vec(elems, |elem| vis.visit_pat(elem)); } PatKind::Path(qself, path) => { vis.visit_qself(qself); vis.visit_path(path); } PatKind::Struct(qself, path, fields, _etc) => { vis.visit_qself(qself); vis.visit_path(path); fields.flat_map_in_place(|field| vis.flat_map_pat_field(field)); } PatKind::Box(inner) => vis.visit_pat(inner), PatKind::Deref(inner) => vis.visit_pat(inner), PatKind::Ref(inner, _mutbl) => vis.visit_pat(inner), PatKind::Range(e1, e2, Spanned { span: _, node: _ }) => { visit_opt(e1, |e| vis.visit_expr(e)); visit_opt(e2, |e| vis.visit_expr(e)); vis.visit_span(span); } PatKind::Tuple(elems) | PatKind::Slice(elems) | PatKind::Or(elems) => { visit_thin_vec(elems, |elem| vis.visit_pat(elem)) } PatKind::Paren(inner) => vis.visit_pat(inner), PatKind::MacCall(mac) => vis.visit_mac_call(mac), } visit_lazy_tts(vis, tokens); vis.visit_span(span); } fn walk_anon_const(vis: &mut T, AnonConst { id, value }: &mut AnonConst) { vis.visit_id(id); vis.visit_expr(value); } fn walk_inline_asm(vis: &mut T, asm: &mut InlineAsm) { // FIXME: Visit spans inside all this currently ignored stuff. let InlineAsm { asm_macro: _, template: _, template_strs: _, operands, clobber_abis: _, options: _, line_spans: _, } = asm; for (op, span) in operands { match op { InlineAsmOperand::In { expr, reg: _ } | InlineAsmOperand::Out { expr: Some(expr), reg: _, late: _ } | InlineAsmOperand::InOut { expr, reg: _, late: _ } => vis.visit_expr(expr), InlineAsmOperand::Out { expr: None, reg: _, late: _ } => {} InlineAsmOperand::SplitInOut { in_expr, out_expr, reg: _, late: _ } => { vis.visit_expr(in_expr); if let Some(out_expr) = out_expr { vis.visit_expr(out_expr); } } InlineAsmOperand::Const { anon_const } => vis.visit_anon_const(anon_const), InlineAsmOperand::Sym { sym } => vis.visit_inline_asm_sym(sym), InlineAsmOperand::Label { block } => vis.visit_block(block), } vis.visit_span(span); } } fn walk_inline_asm_sym( vis: &mut T, InlineAsmSym { id, qself, path }: &mut InlineAsmSym, ) { vis.visit_id(id); vis.visit_qself(qself); vis.visit_path(path); } fn walk_format_args(vis: &mut T, fmt: &mut FormatArgs) { // FIXME: visit the template exhaustively. let FormatArgs { span, template: _, arguments } = fmt; for FormatArgument { kind, expr } in arguments.all_args_mut() { match kind { FormatArgumentKind::Named(ident) | FormatArgumentKind::Captured(ident) => { vis.visit_ident(ident) } FormatArgumentKind::Normal => {} } vis.visit_expr(expr); } vis.visit_span(span); } pub fn walk_expr(vis: &mut T, Expr { kind, id, span, attrs, tokens }: &mut Expr) { vis.visit_id(id); visit_attrs(vis, attrs); match kind { ExprKind::Array(exprs) => visit_thin_exprs(vis, exprs), ExprKind::ConstBlock(anon_const) => { vis.visit_anon_const(anon_const); } ExprKind::Repeat(expr, count) => { vis.visit_expr(expr); vis.visit_anon_const(count); } ExprKind::Tup(exprs) => visit_thin_exprs(vis, exprs), ExprKind::Call(f, args) => { vis.visit_expr(f); visit_thin_exprs(vis, args); } ExprKind::MethodCall(box MethodCall { seg: PathSegment { ident, id, args: seg_args }, receiver, args: call_args, span, }) => { vis.visit_method_receiver_expr(receiver); vis.visit_id(id); vis.visit_ident(ident); visit_opt(seg_args, |args| vis.visit_generic_args(args)); visit_thin_exprs(vis, call_args); vis.visit_span(span); } ExprKind::Binary(_binop, lhs, rhs) => { vis.visit_expr(lhs); vis.visit_expr(rhs); } ExprKind::Unary(_unop, ohs) => vis.visit_expr(ohs), ExprKind::Cast(expr, ty) => { vis.visit_expr(expr); vis.visit_ty(ty); } ExprKind::Type(expr, ty) => { vis.visit_expr(expr); vis.visit_ty(ty); } ExprKind::AddrOf(_kind, _mut, ohs) => vis.visit_expr(ohs), ExprKind::Let(pat, scrutinee, span, _recovered) => { vis.visit_pat(pat); vis.visit_expr(scrutinee); vis.visit_span(span); } ExprKind::If(cond, tr, fl) => { vis.visit_expr(cond); vis.visit_block(tr); visit_opt(fl, |fl| ensure_sufficient_stack(|| vis.visit_expr(fl))); } ExprKind::While(cond, body, label) => { visit_opt(label, |label| vis.visit_label(label)); vis.visit_expr(cond); vis.visit_block(body); } ExprKind::ForLoop { pat, iter, body, label, kind: _ } => { visit_opt(label, |label| vis.visit_label(label)); vis.visit_pat(pat); vis.visit_expr(iter); vis.visit_block(body); } ExprKind::Loop(body, label, span) => { visit_opt(label, |label| vis.visit_label(label)); vis.visit_block(body); vis.visit_span(span); } ExprKind::Match(expr, arms, _kind) => { vis.visit_expr(expr); arms.flat_map_in_place(|arm| vis.flat_map_arm(arm)); } ExprKind::Closure(box Closure { binder, capture_clause, constness, coroutine_kind, movability: _, fn_decl, body, fn_decl_span, fn_arg_span, }) => { visit_constness(vis, constness); coroutine_kind.as_mut().map(|coroutine_kind| vis.visit_coroutine_kind(coroutine_kind)); vis.visit_capture_by(capture_clause); vis.visit_fn(FnKind::Closure(binder, fn_decl, body), *span, *id); vis.visit_span(fn_decl_span); vis.visit_span(fn_arg_span); } ExprKind::Block(blk, label) => { visit_opt(label, |label| vis.visit_label(label)); vis.visit_block(blk); } ExprKind::Gen(_capture_by, body, _kind, decl_span) => { vis.visit_block(body); vis.visit_span(decl_span); } ExprKind::Await(expr, await_kw_span) => { vis.visit_expr(expr); vis.visit_span(await_kw_span); } ExprKind::Assign(el, er, span) => { vis.visit_expr(el); vis.visit_expr(er); vis.visit_span(span); } ExprKind::AssignOp(_op, el, er) => { vis.visit_expr(el); vis.visit_expr(er); } ExprKind::Field(el, ident) => { vis.visit_expr(el); vis.visit_ident(ident); } ExprKind::Index(el, er, brackets_span) => { vis.visit_expr(el); vis.visit_expr(er); vis.visit_span(brackets_span); } ExprKind::Range(e1, e2, _lim) => { visit_opt(e1, |e1| vis.visit_expr(e1)); visit_opt(e2, |e2| vis.visit_expr(e2)); } ExprKind::Underscore => {} ExprKind::Path(qself, path) => { vis.visit_qself(qself); vis.visit_path(path); } ExprKind::Break(label, expr) => { visit_opt(label, |label| vis.visit_label(label)); visit_opt(expr, |expr| vis.visit_expr(expr)); } ExprKind::Continue(label) => { visit_opt(label, |label| vis.visit_label(label)); } ExprKind::Ret(expr) => { visit_opt(expr, |expr| vis.visit_expr(expr)); } ExprKind::Yeet(expr) => { visit_opt(expr, |expr| vis.visit_expr(expr)); } ExprKind::Become(expr) => vis.visit_expr(expr), ExprKind::InlineAsm(asm) => vis.visit_inline_asm(asm), ExprKind::FormatArgs(fmt) => vis.visit_format_args(fmt), ExprKind::OffsetOf(container, fields) => { vis.visit_ty(container); for field in fields.iter_mut() { vis.visit_ident(field); } } ExprKind::MacCall(mac) => vis.visit_mac_call(mac), ExprKind::Struct(se) => { let StructExpr { qself, path, fields, rest } = se.deref_mut(); vis.visit_qself(qself); vis.visit_path(path); fields.flat_map_in_place(|field| vis.flat_map_expr_field(field)); match rest { StructRest::Base(expr) => vis.visit_expr(expr), StructRest::Rest(_span) => {} StructRest::None => {} } } ExprKind::Paren(expr) => { vis.visit_expr(expr); } ExprKind::Yield(expr) => { visit_opt(expr, |expr| vis.visit_expr(expr)); } ExprKind::Try(expr) => vis.visit_expr(expr), ExprKind::TryBlock(body) => vis.visit_block(body), ExprKind::Lit(_token) => {} ExprKind::IncludedBytes(_bytes) => {} ExprKind::Err(_guar) => {} ExprKind::Dummy => {} } visit_lazy_tts(vis, tokens); vis.visit_span(span); } pub fn noop_filter_map_expr(vis: &mut T, mut e: P) -> Option> { Some({ vis.visit_expr(&mut e); e }) } pub fn walk_flat_map_stmt( vis: &mut T, Stmt { kind, mut span, mut id }: Stmt, ) -> SmallVec<[Stmt; 1]> { vis.visit_id(&mut id); let stmts: SmallVec<_> = walk_flat_map_stmt_kind(vis, kind) .into_iter() .map(|kind| Stmt { id, kind, span }) .collect(); if stmts.len() > 1 { panic!( "cloning statement `NodeId`s is prohibited by default, \ the visitor should implement custom statement visiting" ); } vis.visit_span(&mut span); stmts } fn walk_flat_map_stmt_kind(vis: &mut T, kind: StmtKind) -> SmallVec<[StmtKind; 1]> { match kind { StmtKind::Let(mut local) => smallvec![StmtKind::Let({ vis.visit_local(&mut local); local })], StmtKind::Item(item) => vis.flat_map_item(item).into_iter().map(StmtKind::Item).collect(), StmtKind::Expr(expr) => vis.filter_map_expr(expr).into_iter().map(StmtKind::Expr).collect(), StmtKind::Semi(expr) => vis.filter_map_expr(expr).into_iter().map(StmtKind::Semi).collect(), StmtKind::Empty => smallvec![StmtKind::Empty], StmtKind::MacCall(mut mac) => { let MacCallStmt { mac: mac_, style: _, attrs, tokens } = mac.deref_mut(); visit_attrs(vis, attrs); vis.visit_mac_call(mac_); visit_lazy_tts(vis, tokens); smallvec![StmtKind::MacCall(mac)] } } } fn walk_vis(vis: &mut T, visibility: &mut Visibility) { let Visibility { kind, span, tokens } = visibility; match kind { VisibilityKind::Public | VisibilityKind::Inherited => {} VisibilityKind::Restricted { path, id, shorthand: _ } => { vis.visit_id(id); vis.visit_path(path); } } visit_lazy_tts(vis, tokens); vis.visit_span(span); } fn walk_capture_by(vis: &mut T, capture_by: &mut CaptureBy) { match capture_by { CaptureBy::Ref => {} CaptureBy::Value { move_kw } => { vis.visit_span(move_kw); } } } /// Some value for the AST node that is valid but possibly meaningless. Similar /// to `Default` but not intended for wide use. The value will never be used /// meaningfully, it exists just to support unwinding in `visit_clobber` in the /// case where its closure panics. pub trait DummyAstNode { fn dummy() -> Self; } impl DummyAstNode for Option { fn dummy() -> Self { Default::default() } } impl DummyAstNode for P { fn dummy() -> Self { P(DummyAstNode::dummy()) } } impl DummyAstNode for Item { fn dummy() -> Self { Item { attrs: Default::default(), id: DUMMY_NODE_ID, span: Default::default(), vis: Visibility { kind: VisibilityKind::Public, span: Default::default(), tokens: Default::default(), }, ident: Ident::empty(), kind: ItemKind::ExternCrate(None), tokens: Default::default(), } } } impl DummyAstNode for Expr { fn dummy() -> Self { Expr { id: DUMMY_NODE_ID, kind: ExprKind::Dummy, span: Default::default(), attrs: Default::default(), tokens: Default::default(), } } } impl DummyAstNode for Ty { fn dummy() -> Self { Ty { id: DUMMY_NODE_ID, kind: TyKind::Dummy, span: Default::default(), tokens: Default::default(), } } } impl DummyAstNode for Pat { fn dummy() -> Self { Pat { id: DUMMY_NODE_ID, kind: PatKind::Wild, span: Default::default(), tokens: Default::default(), } } } impl DummyAstNode for Stmt { fn dummy() -> Self { Stmt { id: DUMMY_NODE_ID, kind: StmtKind::Empty, span: Default::default() } } } impl DummyAstNode for Crate { fn dummy() -> Self { Crate { attrs: Default::default(), items: Default::default(), spans: Default::default(), id: DUMMY_NODE_ID, is_placeholder: Default::default(), } } } impl DummyAstNode for crate::ast_traits::AstNodeWrapper { fn dummy() -> Self { crate::ast_traits::AstNodeWrapper::new(N::dummy(), T::dummy()) } } #[derive(Debug)] pub enum FnKind<'a> { /// E.g., `fn foo()`, `fn foo(&self)`, or `extern "Abi" fn foo()`. Fn(&'a mut FnSig, &'a mut Generics, &'a mut Option>), /// E.g., `|x, y| body`. Closure(&'a mut ClosureBinder, &'a mut P, &'a mut P), }